Aurora Gómez-Durán

Mitochondrial DNA background modulates the assembly kinetics of OXPHOS complexes in a cellular model of mitochondrial disease

Lebers hereditary optic neuropathy (LHON), the most frequent mitochondrial disorder, is mostly due to three mitochondrial DNA (mtDNA) mutations in respiratory chain complex I subunit genes: 3460/ND1, 11778/ND4 and 14484/ND6. Despite considerable clinical evidences, a genetic modifying role of the mtDNA haplogroup background in the clinical expression of LHON remains experimentally unproven. We investigated the effect of mtDNA haplogroups on the assembly of oxidative phosphorylation (OXPHOS) complexes in transmitochondrial hybrids (cybrids) harboring the three common LHON mutations. The steady-state levels of respiratory chain complexes appeared normal in mutant cybrids. However, an accumulation of low molecular weight subcomplexes suggested a complex I assembly/stability defect, which was further demonstrated by reversibly inhibiting mitochondrial protein translation with doxycycline. Our results showed differentially delayed assembly rates of respiratory chain complexes I, III and IV amongst mutants belonging to different mtDNA haplogroups, revealing that specific mtDNA polymorphisms may modify the pathogenic potential of LHON mutations by affecting the overall assembly kinetics of OXPHOS complexes.

Mitochondrial pharmacogenomics: barcode for antibiotic therapy

Ribosomal RNA (rRNA)-targeting drugs inhibit protein synthesis and represent effective antibiotics for the treatment of infectious diseases. Given the bacterial origins of mitochondria, the molecular and structural components of the protein expression system are much alike. Moreover, the mutational rate of mitochondrial rRNAs is higher than that of nuclear rRNAs, and some of these mutations might simulate the microorganisms rRNA structure. Consequently, individuals become more susceptible to antibiotics, the mitochondrial function is affected and toxic effects appear. Systems are available to analyze the interaction between antibiotics and mitochondrial DNA genetic variants, thus making a pharmacogenomic approach to antibiotic therapy possible.

Cybrids for Mitochondrial DNA Pharmacogenomics

Preclinical Research

Diseases of the human mitochondrial oxidative phosphorylation system.

Mitochondrial diseases, or diseases of the oxidative phosphorylation system, consist of a group of disorders originated by a deficient synthesis of ATP. This system is composed of proteins codified in the two genetic systems of the cell, the nuclear and the mitochondrial genomes, and, therefore, the mode of inheritance could be either mendelian or maternal. The diseases can also appear sporadically. Due to the central role that mitochondria play in cellular physiology, these diseases are a social and health problem of great importance. They are considered rare diseases; however, together they constitute a large variety of genetic disorders. It is also believed that mitochondria are involved, directly or indirectly, in many other human diseases, mainly in age-related diseases. This review will focus mainly on describing the special characteristics of the mitochondrial genetic system and the diseases caused by mitochondrial DNA mutations. We will also note the difficulties in studying these pathologies, and the possible involvement of the genetic variability of the mitochondrial genome in the development of these diseases.

Read-through therapy for mitochondrial DNA nonsense mutations

Disorders resulting from mitochondrial DNA (mtDNA) mutations, including nonsense mutations, do not yet have causal treatments. As we discuss here, read-through therapies appear to be a promising approach to the treatment of disorders arising from nuclear DNA (nDNA) nonsense mutations. The genetics of mitochondrial DNA suggest that this therapy will also be successful in the treatment of mitochondriopathies.

Stressed cybrids model demyelinated axons in multiple sclerosis

Multiple sclerosis is likely caused by a complex interaction of multiple genes and environmental factors. The contribution of mitochondrial DNA genetic backgrounds has been frequently reported. To evaluate the effect of mitochondrial DNA haplogroups in the same genetic and environmental circumstances, we have built human transmitochondrial cell lines and simulated the effect of axon demyelination, one of the hallmarks of multiple sclerosis pathology, by altering the ionic gradients through the plasmalemma and increasing ATP consumption. In this model, mitochondrial biogenesis is observed. This process is larger in Uk cybrids, which mirrors their lower oxidative phosphorylation capacity in basal conditions. This model replicates a process occurring in both patients suffering from multiple sclerosis and several animal models of axon demyelination. Therefore, it can be used to analyze the contribution of various mitochondrial DNA genotypes to multiple sclerosis. In this sense, a longer or stronger energy stress, such as that associated with demyelinated axons in multiple sclerosis, could make Uk individuals more susceptible to this pathology. Finally, pharmacologic compounds targeted to mitochondrial biogenesis could be a potential therapy for multiple sclerosis.